-from pypol import *
-
-def affine_derivative_closure(T, x0s):
-
- xs = [Symbol("{}'".format(x0.name)) for x0 in x0s]
- dxs = [Symbol('d{}'.format(x0.name)) for x0 in x0s]
- k = Symbol('k')
-
- for x in T.symbols:
- assert x in x0s + xs
- for dx in dxs:
- assert dx.name not in T.symbols
- assert k.name not in T.symbols
-
- T0 = T
-
- T1 = T0
- for i, x0 in enumerate(x0s):
- x, dx = xs[i], dxs[i]
- T1 &= Eq(dx, x - x0)
-
- T2 = T1.project_out(T0.symbols)
-
- T3_eqs = []
- T3_ins = []
- for T2_eq in T2.equalities:
- c = T2_eq.constant
- T3_eq = T2_eq + (k - 1) * c
- T3_eqs.append(T3_eq)
- for T2_in in T2.inequalities:
- c = T2_in.constant
- T3_in = T2_in + (k - 1) * c
- T3_ins.append(T3_in)
- T3 = Polyhedron(T3_eqs, T3_ins)
- T3 &= Ge(k, 0)
-
- T4 = T3.project_out([k])
- for i, dx in enumerate(dxs):
- x0, x = x0s[i], xs[i]
- T4 &= Eq(dx, x - x0)
- T4 = T4.project_out(dxs)
-
- return T4
-
-i0, j0, i, j = symbols(['i', 'j', "i'", "j'"])
-T = Eq(i, i0 + 2) & Eq(j, j0 + 1)
-
-print('T =', T)
-Tstar = affine_derivative_closure(T, [i0, j0])
-print('T* =', Tstar)
+# This is an implementation of the algorithm described in
+#
+# [ACI10] C. Ancourt, F. Coelho and F. Irigoin, A modular static analysis
+# approach to affine loop invariants detection (2010), pp. 3 - 16, NSAD 2010.
+#
+# to compute the transitive closure of an affine transformer. A refined version
+# of this algorithm is implemented in PIPS.
+
+from linpy import Dummy, Eq, Ge, Polyhedron, symbols
+
+
+class Transformer:
+
+ def __new__(cls, polyhedron, range_symbols, domain_symbols):
+ self = object().__new__(cls)
+ self.polyhedron = polyhedron
+ self.range_symbols = range_symbols
+ self.domain_symbols = domain_symbols
+ return self
+
+ @property
+ def symbols(self):
+ return self.range_symbols + self.domain_symbols
+
+ def star(self):
+ delta_symbols = [symbol.asdummy() for symbol in self.range_symbols]
+ k = Dummy('k')
+ polyhedron = self.polyhedron
+ for x, xprime, dx in zip(
+ self.range_symbols, self.domain_symbols, delta_symbols):
+ polyhedron &= Eq(dx, xprime - x)
+ polyhedron = polyhedron.project(self.symbols)
+ equalities, inequalities = [], []
+ for equality in polyhedron.equalities:
+ equality += (k-1) * equality.constant
+ equalities.append(equality)
+ for inequality in polyhedron.inequalities:
+ inequality += (k-1) * inequality.constant
+ inequalities.append(inequality)
+ polyhedron = Polyhedron(equalities, inequalities) & Ge(k, 0)
+ polyhedron = polyhedron.project([k])
+ for x, xprime, dx in zip(
+ self.range_symbols, self.domain_symbols, delta_symbols):
+ polyhedron &= Eq(dx, xprime - x)
+ polyhedron = polyhedron.project(delta_symbols)
+ return Transformer(polyhedron, self.range_symbols, self.domain_symbols)
+
+
+if __name__ == '__main__':
+ i0, i, j0, j = symbols('i0 i j0 j')
+ transformer = Transformer(Eq(i, i0 + 2) & Eq(j, j0 + 1),
+ [i0, j0], [i, j])
+ print('T =', transformer.polyhedron)
+ print('T* =', transformer.star().polyhedron)